Tau-induced memory loss in Alzheimer’s mice is reversible

Max Planck study raises hopes for the development of effective therapies

February 15, 2011

Amyloid-beta and tau protein deposits in the brain are characteristic features of Alzheimer disease. The effect on the hippocampus, the area of the brain that plays a central role in learning and memory, is particularly severe. However, it appears that the toxic effect of tau protein is largely eliminated when the corresponding tau gene is switched off. Researchers from the Max Planck Research Unit for Structural Molecular Biology at DESY in Hamburg have succeeded in demonstrating that once the gene is deactivated, mice with a human tau gene, which previously presented symptoms of dementia, regain their ability to learn and remember, and that the synapses of the mice also reappear in part. The scientists are now testing active substances to prevent the formation of tau deposits in mice. This may help to reverse memory loss in the early stages of Alzheimer disease – in part, at least.

Left: A normal mouse learns to swim from the edge of a water basin to an invisible platform (under the water) and quickly remembers how to find the way to the platform (red path). Middle: A mouse with too much aggregated tau protein in its brain and already suffering from Alzheimer’s disease finds it difficult to learn about the path and swims aimlessly around the basin. Right: When the gene for the tau protein has been switched off for a few weeks, the Alzheimer’s mouse regains its ability to learn.

Left: A normal mouse learns to swim from the edge of a water basin to an invisible platform (under the water) and quickly remembers how to find the way to the platform (red path). Middle: A mouse with too much aggregated tau protein in its brain and already suffering from Alzheimer’s disease finds it difficult to learn about the path and swims aimlessly around the basin. Right: When the gene for the tau protein has been switched off for a few weeks, the Alzheimer’s mouse regains its ability to learn.

Whereas aggregated amyloid-beta protein forms insoluble clumps between the neurons, the tau protein accumulates inside them. Tau protein stabilises the tube-shaped fibers of the cytoskeleton, known as microtubules, which provide the “rails” for cellular transport. In Alzheimer disease, excess phosphate groups cause the tau protein to malfunction and form clumps (the ‘neurofibrillary tangles’). As a result, nutrient transport breaks down and the neurons and their synapses die off. This process is accompanied by the initial stage of memory loss.

Together with colleagues from Leuven, Hamburg and Erlangen, Eva and Eckhard Mandelkow’s team from the Max Planck Research Unit for Structural Molecular Biology generated regulatable transgenic mice with two different human tau gene variants that can be switched on and off again: one group was given a form of the protein that cannot become entangled (anti-aggregant), and a second was provided with the code for the strongly aggregating protein variant (pro-aggregant). The mice with the first form developed no Alzheimer symptoms; the rodents that were given the pro-aggregant tau developed the disease.

The scientists measured the mice’s memory loss with the help of a swimming test: the healthy mice quickly learn how to find a life-saving platform located under the surface of the water in a water basin. In contrast, the transgenic animals, which have the additional pro-aggregant tau gene paddle aimlessly around the basin until they accidentally stumble on the platform; they require over four times more time to do this than their healthy counterparts. However, if the mutated toxic tau gene is switched off again, the mice learn to reach “dry land” with ease just a few weeks later. As a control, the mice with the anti-aggregant form of tau have no defects in learning, just as normal non-transgenic mice.

Surprising tissue results

Tissue tests showed that, as expected, no tau clumps had formed in the brains of the first group of mice expressing anti-aggregant tau. In the second group – the mice suffering from Alzheimer’s – co-aggregates from human tau and “mouse tau” were formed - against expectations, because tau protein from mice does not usually aggregate. “Even more astonishingly, weeks after the additional gene had been switched off, the aggregated human tau had dissolved again. However, the ‘mouse tau’ remained clumped. Despite this, the mice were able to learn and remember again,” says Eckhard Mandelkow. More precise tests revealed that new synapses had actually formed in their brains.

The scientists concluded from this that mutated or pathological tau can alter healthy tau. It appears that pro-aggregant tau can act similar to a crystal nucleus – once it has started to clump up, it drags neighboring "healthy" tau into the clumps as well. This is what makes the process so toxic to the neurons. “The really important discovery here, however, is that the progression of Alzheimer’s disease can be reversed in principle - at least at an early stage of the illness before too many neurons have been destroyed,” explains Eva Mandelkow who, together with her husband, will be awarded the Potamkin Prize 2011 for Alzheimer's disease research, which is sponsored by the American Academy of Neurology.

The aggregation of tau proteins, however, cannot simply be switched off in humans the way it can in the transgenic mice. Nevertheless, special substances exist that could dissolve the tau aggregates. By screening 200,000 substances, the Hamburg researchers have already identified several classes of active substances that could re-convert the tau aggregates into soluble tau. These are now being tested on animals.